WO2001037487A2 - Intelligent data line - Google Patents

Abstract

The invention relates to an intelligent data line for data networks, comprising a circuit (10) for identifying and managing cable-specific, network-specific, and/or user-specific characteristics, said circuit (10) comprising a read/write memory (2) and a relaying facility (1) which controls the flow of data between the data line (4) and the read/write memory (2).

Description

Intelligent data line

The invention relates to an intelligent data line for data networks, with a circuit for identifying and managing cable-specific, network-specific or user-specific data.

Traditionally, end devices, such as computers or printers, are connected to one another via data lines. The interconnected terminals form a data network in which the various terminals can communicate with one another via data lines. Due to the increasing complexity of these networks, the number and length of data lines connecting the end devices is increasing. In order to be able to manage or maintain such a network, it is necessary to identify and locate the data lines and end devices of the network. Since the data lines are often very long and are laid in special cable channels, their location is often cumbersome and time-consuming. An intelligent data line for localizing a cable of a data line network is known from DE 1 98 60 708.3, which represents a post-published state of the art. In this earlier arrangement, in order to identify the data lines that connect two devices of a network, a data packet is sent from one terminal to the other. Each data line adds an individual cable identifier to the data packet when the data packet passes the data line. The data packet received by a terminal is then sent back, and the attached cable identifiers are read from the data packet. From the number and order of the individual cable identifiers received, it is recognized in which order and via which cables the end devices are connected to one another. With this method, it can be recognized how end devices of a network are connected to one another, but the end devices must be switched on so that the sent data packet can be received or sent back. In addition, end devices must be connected to the data line ends of the network and the identifiers of the end devices must be known in order to be able to send signals over the data line.

Assigning identifiers to end devices in a network can also lead to further disadvantages. The identifier of a terminal is used to uniquely identify a terminal in a network. It must therefore be ensured that the same identifier is not assigned to two end devices, which can be very complex under certain circumstances if not all connected end devices are known.

It is an object of the present invention to provide an intelligent data line in which cable-specific, network-specific and / or user-specific data can be stored, updated and remotely queried, in particular the characteristic data of the data line and connected terminals can be assigned to one another. This object is solved by the features of claim 1. According to the invention, a circuit is integrated in the intelligent data line. This circuit comprises a read / write memory and a switching device. The switching device controls the data flow between, the data line and the read / write memory.

According to the invention, information about terminal devices and data lines of the network can be stored in the intelligent data line and linked to one another by the switching device and the read / write memory and can be called up remotely via the switching device. Thus, network and data line information, in particular also information about assigned or connected to the line terminals can be called up directly from the data lines of the network without having to send a signal to another switched on terminal of the network. According to the invention, all information about the network can be read from the data lines by a terminal. All assigned IDs for the connected end devices can thus be called up centrally before a new ID is assigned. It is also possible to save the identifiers for end devices in the data lines to which they are connected. Each end device then receives its identifier in the network by reading the identifier from the intelligent data line to which the end device is connected. Because each terminal is assigned a cable line, the assignment of identifiers for terminals can be followed by entering an individual identifier for terminals in each cable.

In an advantageous embodiment of the present invention, memory management is additionally connected to the switching device. If a terminal connected to the intelligent data line wants to read characteristic data from the read / write memory, it sends a corresponding command in the form of control data to the switching device. The switching device transmits all control data received to the memory manager, which then causes that the requested characteristic data are read from the read / write memory and fed into the data network via the switching device and transmitted to the corresponding terminal.

According to the invention, characteristic data are written into the read / write memory if they are transmitted to the circuit with corresponding control data. On the basis of the control data received, the memory management causes the identification data to be stored in the read / write memory by the switching device.

Another advantageous embodiment of the present invention is to provide the circuit of the intelligent data line with an independent energy supply. The circuit is supplied with energy either via a feed circuit, which draws the necessary energy either directly from a power supply network or via the data line. The feed circuit converts the received energy in such a way that it is suitable for supplying the components of the circuit. It is also possible to automatically switch the energy supply via the data line and / or from the energy supply network to the respective other type of food if the energy supply via one of the tapping points is no longer guaranteed. Due to the independent and permanent power supply of the intelligent data line, the read / write memory of the intelligent data line can be accessed at any time.

The switching of the intelligent data line can also have a read-only memory. The data in the read memory can only be called up but not overwritten. This ensures that, for example, cable-specific information such as the identifier of the data line cannot be overwritten.

A further advantageous embodiment of the present invention provides that a transmitting / receiving device in the circuit to the switching device connected. The transceiver can send and receive electromagnetic signals. The memory in the circuit can thus be accessed by means of an external transceiver. Characteristic data can thus be read into the intelligent data line or read out from the intelligent data line without a terminal device having to be connected to the data line.

Alternatively, an external device can be connected directly to a connection that is connected to the switching device. The memories in the circuit are accessed via the connection in the manner described above.

According to the invention, in addition to the cable-specific characteristic data, network-specific characteristic data, in particular also the characteristic data of terminal devices connected to the data line, can thus preferably be recorded and stored in the circuit and fed into the data network during a query process and received at one of the terminal devices of the data network. In addition, additional external, i.e. User-specific characteristic data, for example storing inventory data in the circuit and assigning it to the characteristic data of the data line.

The circuit preferably contains a control device which modifies the data flow in the data line when certain characteristic data are recognized and, for example, prevents the data flow to a terminal connection. The intelligent data line according to the invention can act as an independent communication partner if, for example, no terminal is active. The circuit enables cable identification data and the identification data of terminal devices to be linked to one another by identification.

The intelligent data line is able to analyze the data streams to and from the connected end device and modify them if necessary. This is achieved by the circuit according to the invention, which is preferably integrated in the cable guaranteed. In addition, it is possible to provide a connection for external information transmitters on the circuit, which is preferably designed as a module, which contain individual inventory information as a type of electronic device label, which is transmitted to the circuit via a plug-in cable. The modification of the data streams consists in generating additional information in a data packet of conventional network protocols - preferably TCP / IP - which can be identified by significant bit sequences and forwarding the respective sending direction of the data packet or sending it back to the transmitter in the opposite sending direction. The energy required to operate the circuit, which is also to be used to power the electronic device labels, may need to be provided by an external power supply.

The circuit for the intelligent data line is preferably integrated in the data line, but it can alternatively also be designed as a separate module which is connected to the data line via a plug connection. The circuit according to the invention remains functional even when the terminal is switched off or disconnected at the end of the data line. The circuit is inserted into the data line or connected to the data line in such a way that the data line functions as a normal cable even if the power supply fails. The additional information to be generated by modifying a data area provided specifically for this purpose within the data packet consists of a cable-specific identifier stored in the circuit, possibly user-specific information stored and the list of individual inventory information or status information.

The following functions must be identifiable and executable using suitable bit sequences:

Send the modified data packet in the sending direction; send modified data packet back to sender; Update of the operating software of the circuit (down ioading); Update of user-specific information held in the circuit including the cable-specific identification code; Function test with status information back to the transmitter; Query the user-specific information back to the sender; Activation and deactivation of the data path to the data terminal.

Advantageous developments of the invention are characterized in the subclaims.

Exemplary embodiments for the intelligent data line are described in more detail below with reference to the drawings:

Show it:

Figure 1 shows the structure of an intelligent data line according to a first embodiment;

Figure 2 is a flow chart showing the process by which data from the

Read / write memory of the data line can be read out;

FIG. 3 is a flowchart describing the sequence by which data is written into the read / write memory of the data line;

Figure 4 shows a second embodiment of the invention;

Figure 5 shows a third embodiment of the invention;

Figure 6 shows a fourth embodiment of the invention;

Figure 7 shows a fifth embodiment of the invention; Figure 8 shows a sixth embodiment of the invention;

FIG. 9 shows an exemplary embodiment for a structural design of an intelligent data line, comprising two plug-in modules and a cable when plugged together;

10 shows the two plug-in modules and the cable from FIG. 9 in the non-assembled state;

Figure 1 1 the two plug-in modules from Figures 9 and 10 plugged together directly.

The first exemplary embodiment of the invention is described below. 1 shows a data line 4, a switching device 1 in the data line 4, a read / write memory 2 and a memory manager 3, both of which are connected to the switching device 1. The switching device 1 mediates data between the data line and the read / write memory. The memory management 3, the read / write memory 2 and the data line 4 are connected to the switching device.

FIG. 2 schematically explains how a device connected to the data line 4 can access the read / write memory 2 of the data line 4. A connected terminal sends a control signal to the switching device 1 via the data line 4. The switching device 1 recognizes the control signal and transmits it to the memory manager 3. The memory manager 3 takes the instruction from the received control signal to read certain characteristic data from the read / write memory 2 and to transmit it via the data line 4 to a connected terminal. The memory manager 3 executes this instruction by controlling the switching device 1 and the read / write memory 2 accordingly. The requested data packet is then sent from the switching device 1 out of the read / write memory 2 read out and conveyed to the corresponding end device.

FIG. 3 shows how characteristic data is read into the read / write memory 2 of the intelligent data line from a terminal connected to the data line 4. The characteristic data to be read are transmitted to the switching device 1 with a control signal. The switching device 1 transmits the control signal to the memory manager 3. The memory manager 3 takes the instruction from the received control signal to store the received characteristic data in the read / write memory 2 at a specific location. The memory manager 3 executes this instruction by controlling the switching device 1 accordingly. The received data packet is then written by the switching device 1 into the read / write memory 2.

Figure 4 shows a second embodiment of the intelligent data line. In this exemplary embodiment, the circuit 10 of the intelligent data line consists of a switching device 1, which is located in the data line 4, a read / write memory 2, a memory management 3 and a read memory 5. The switching device 1 mediates data between the components of the circuit 10 and terminals, which are connected to the data line 4. The memory management 3, the read / write memory 2 and the read memory 5 are connected to the switching device 1. The memory management 3 is connected to the read / write memory 2.

In this example, the read / write memory 2 or the read memory 5 of the intelligent data line is accessed in a manner similar to that in the first exemplary embodiment. First, control data are transmitted to the administration 3 via the switching device 1, whereupon the administration 3 recognizes this control data and controls the writing of data into the read / write memory 2 or the reading of data from the read / write memory 2 and / or the read memory 5 , The control data must therefore also contain information about which of the two memories is to be accessed and which Administration 3 must be able to recognize and implement this information. It is not possible to read data into the read memory 5 of the circuit 4 of the intelligent data line. This ensures that data in the read memory 5 cannot be overwritten.

It therefore makes sense to store information in the read memory 5 from the manufacturer, so that a customer can call up important information about the purchased product at any time. This information can be used to identify the intelligent data line itself and its components. However, the information stored in the read memory 5 can also be valuable in the repair or maintenance of the intelligent data line. For example, the read memory 5 can contain information about which components the data line consists of, which identifier these components and / or the intelligent data line have as such, which physical properties the data line 4 had on delivery from the manufacturer and when the manufacturer's guarantee expires. If a faulty intelligent data line is sent back to the manufacturer before the guarantee expires, the cause can be researched on the basis of the information stored in the read memory 5, which is why the data line did not meet the expected requirements. That is, the information stored in the read memory 5 can also be useful for quality control in the production of the intelligent data line. For this purpose, information relevant to production is stored in the read memory 5, for example the machines or tools with which the intelligent data line was produced.

FIGS. 5 and 6 show further exemplary embodiments of the present invention. In both exemplary embodiments, an additional device is connected to the switching device 1. The additional device is used to exchange information with the intelligent data line. The memory of the circuit 4 of the intelligent data line is accessed analogously to the exemplary embodiments described above. In Figure 5 is the additional Device, a transceiver 6 that can send and receive information wirelessly. The memory of the intelligent data line can thus be accessed wirelessly by means of a corresponding external device.

In FIG. 6, the additional device is a connection 7, via which a suitable device is connected to the circuit 4 of the intelligent data line, and the memory of the intelligent data line can be accessed.

FIG. 7 shows an embodiment with an independent energy supply. A circuit 10 according to one of the above exemplary embodiments is accommodated in the intelligent data line. A power supply controller 1 3 supplies the components of the circuit 10 with the required electrical energy. The power supply control 1 3 is connected to the data line 4 via a second power supply unit 1 2 and additionally or alternatively via a first power supply unit 1 1 to a power supply network. The power supply control 1 3 detects whether an adequate power supply to the circuit can be provided by one of the power supply units 1 1 or 1 2 and, if necessary, switches between the power supply lines, so that a stable power supply to the circuit 1 0 is ensured. The power supplies 1 1 and 1 2 convert the respectively received electrical energy in such a way that it is suitable for the operation of the circuit 4 and pass it on to the power supply control 1 3.

Figure 8 shows another embodiment of the intelligent data line. The components shown with the reference numerals 1, 2, 3, 4 correspond to the components described above with the same reference numerals. In this exemplary embodiment, a detection unit 8 is additionally connected to the switching device 1. The switching device 1 transmits signals to the detection unit 8. The switching device 1 otherwise fulfills the same tasks as in the exemplary embodiment 1 according to FIG. 1. The detection unit 8 analyzes the received signal before it forwards the signal to the switching device 1 and detects signal distortions that occur, for example, due to a damaged data line 4. The detection unit 8 detects, for example on the basis of a signal analysis, whether a signal reflection occurs in the data line 4 or at an open or inadequately closed data line end. The distinction between signal reflections at an open line end and signal reflections in the data line 4 itself is determined on the basis of the signal propagation time of the reflected signal, since a signal reflection in the data line 4 always has a shorter signal propagation time than a reflected signal at the intended data line end. If a signal reflection is detected in the data line 4, the compensation unit calculates the location at which the reflection occurs, based on the transit time of the reflected signal. All analysis results of the compensation unit 8 are stored in the read / write memory 2 via the switching device.

The detection unit is able to continuously monitor the transmission properties of the data line 4 and the state of the data line 4 in the write mode on the basis of the analysis of received signals. Read memory 2 to save. If the information transmission is faulty due to a damaged data line or has completely broken down, it is possible to read out information about the state of the data line 4 from the circuit 10 of the intelligent data line via an undamaged end of the data line. In the present exemplary embodiment, this information could alternatively also be read out via the transceiver 6 or the connection 7. It is thus possible, in the event of transmission difficulties due to defective data lines 4, to easily identify the data line 4 which is causing the errors. Before damage or wear of the data line 4 leads to the fact that the information transmission in a network is faulty or breaks down, the data line 4 can be replaced or repaired.

A data line and the data line 4 are advantageously constructed modularly. An embodiment there is shown in Figures 9 and 10. The circuit 10 is integrated in a first plug-in module 20, which has a plug connection 22, which is designed to be plugged into a compatible plug connection 24 at a first end of a cable 26. The cable 26 has at its second end a plug connection 28 which is designed to be plugged into a second plug module 30. The second plug-in module 30 comprises an inventory data memory 32.

As shown in FIG. 10, the first plug-in module 20, the cable 26 and the second plug-in module 30 can be separated from one another.

As shown in Figure 1 1, the first and the second plug-in module can also be plugged together directly, since their corresponding plug connections 22 and 28 are designed accordingly.

The first plug-in module 20 contains the circuit 10 and thus provides the entire functionality for identifying the data line. The first plug-in module 20 can be connected, for example, to the end of a data line permanently installed in a building, so that it can be identified. The connection to this fixed data line can be made by plugging in or permanently connecting the plug-in module 20. The cable 26 then serves to connect a terminal. The second plug-in module 30 is designed for insertion or permanent connection to a terminal and has a corresponding connection 34. The second plug-in module 30 can remain permanently connected to the terminal, since the connection to the cable 26 or the first plug-in module 20 can be released. An inventory ID is stored in the inventory data memory 32 of the second plug-in module 30, which is assigned to this terminal by connecting the second plug-in module 30 to a terminal and can also remain assigned to the terminal when the cable 26 is disconnected. The circuit 10 in the first plug-in module 20 is designed in such a way that it can write inventory data via the switching device (1) into the read / write memory (2). The connection between the circuit 10 in the first plug-in module 20 and the inventory data memory 32 in the second plug-in module 30 is established either by the cable 26, as shown in FIG. 9, or by directly plugging the first plug-in module 20 into the second plug-in module 30 , as shown in Figure 1 1.

Claims

Expectations

1 . Intelligent data line for data networks, with a circuit (10) for identifying and managing cable-specific, network-specific and / or user-specific characteristic data, the circuit (10) comprising a read / write memory (2), and a switching device (1), wherein the switching device controls the data flow between the data line (4) and the read / write memory (2).

2. Intelligent data line according to claim 1 with a circuit (1 0), wherein the circuit (1 0) comprises a memory management (3) for controlling the switching device (1), the switching device (1) recognizes control data and to the memory management (3) mediates, and the memory management (3) takes commands for controlling the switching device (1) from the received control data and executes the commands.

3. Intelligent data line according to one of the preceding claims, wherein the memory management (3) transfers control commands to the switching device (1), in particular to write characteristic data supplied via the data line into the read / write memory (2) or to write certain characteristic data from the write / Read memory (2) and feed it into the data line.

4. Intelligent data line according to one of the preceding claims, wherein the circuit (1 0) comprises a supply circuit (1 1) which can be connected to a power supply network by means of a supply line in order to connect the circuit (1 0) with one for the operation of the circuit ( 1 0) to supply the necessary energy.

5. Intelligent data line according to one of the preceding claims, wherein the Circuit (1 0) contains a supply circuit (1 2), the energy supply via the data line (4).

6. Intelligent data line according to claim 4 or 5, wherein the circuit comprises an energy supply control (1 3) which switches automatically between the energy supply via the data line (4) or via the supply line in order to ensure a stable energy supply to the circuit (10).

7. Intelligent data line according to one of the preceding claims, wherein the circuit (10) comprises a read memory (5), and the switching device the data flow between the read memory (5), the data line (4) and the read / write Memory (2) controls.

8. Intelligent data line according to claim 7, wherein the cable-related information is stored in a programmable read-only memory (5), and the network-related information is stored in the read-write memory (2).

9. Intelligent data line according to one of the preceding claims, wherein the circuit (10) comprises a transceiver (6) for transmitting and receiving electromagnetic signals, and the switching device the data flow between the transceiver (6) and the read / write Memory (2) controls.

10. Intelligent data line according to one of the preceding claims, wherein the circuit (1 0) comprises a connection (7) for an external device, and the switching device controls the data flow between the connection (7) and the read / write memory (2) ,

1 1. Intelligent data line according to one of the preceding claims, wherein the Circuit (1 0) has a detection unit (8) which receives signals from the switching device (1) and detects the signal path covered by the signal.

1 2. Intelligent data line according to claim 1 1, wherein the detection unit (8) detects signal distortion based on the signal curve.

1 3. Intelligent data line according to claim 1 1, wherein the detection unit (8) detects signal reflections on the basis of the signal profiles.

14. Intelligent data line according to claim 1 1, wherein the detection unit (8) recognizes the location of a signal reflection based on the transit time of reflected signals.

1 5. Intelligent data line according to claim 1 0 to 1 2, wherein the waveforms determined by the detection unit (8), signal distortion, signal reflections and the locations of signal reflections in the read / write memory (2) are stored.

1 6. Intelligent data line according to one of claims 1 1 to 1 5, characterized in that the detection unit (8) detects an open end of the data line.

17. Intelligent data line according to one of the preceding claims, characterized by a control circuit which prevents the flow of data to the terminal connection when the recognition unit (8) recognizes certain predetermined characteristic data.

1 8. Intelligent data line according to one of the preceding claims, characterized in that the circuit (1 0) the state of the terminal connection or the operating state of the connected terminal identified and stores the relevant data.

1 9. Intelligent data line according to claim 1 8, characterized in that the switching device (1) feeds stored characteristic data controlled by the memory management (3) or by an external request into the data network.

20. Intelligent data line according to one of the preceding claims, characterized in that the circuit (1 0) analyzes the data streams from or to the connected terminal and modifies them if necessary.

21. Intelligent data line according to claim 20, characterized in that for the modification of the data streams in data packets of conventional data network protocols, the cable-specific characteristic data or the operating state of the cable or the connected terminal device are meant and the modified data packets are forwarded in the transmission direction or sent back to the transmitter.

22. Intelligent data line according to one of the preceding claims, characterized in that external characteristic data, for example inventory data via the data line and the switching device (1) can be written into and read from the read / write memory.

23. Intelligent data line according to one of the preceding claims, characterized in that the circuit (10) is arranged in a first plug-in unit (20) which can be releasably connected directly or via a cable (26) to a second plug-in unit (30) that data can be transmitted from the second plug-in unit (30) to the first plug-in unit (20).

24. Intelligent data line according to claim 23, characterized in that the second plug-in unit (30) comprises an inventory data memory (32) for an identification identifier.

25. Intelligent data line according to claim 23 or 24, characterized in that the data line comprises the first plug-in unit (20), the cable (26) and the second plug-in unit (30), the first plug-in unit (20), the second plug-in unit (30 ) and the cable (26) are to be detachably plugged together.

26. The first plug-in unit (20) for an intelligent data line according to one of claims 23 to 25, characterized in that it has a plug-in connection (22) which is designed for the first plug-in unit (20) either with the cable (26) or the to connect the second plug-in unit (30).

27. Second plug-in unit (30) for an intelligent data line according to one of claims 23 to 25, characterized in that it has a plug-in connection (29) which is designed for the second plug-in unit (30) either with the cable (26) or the to connect the first plug-in unit (20).

28. Cable (26) for an intelligent data line according to one of claims 23 to 25, characterized in that the cable (26) has two plug connections (24, 28), of which one (24) is designed, the cable (26) to connect to the first plug-in unit (20), and of which the other plug-in connection (28) is designed to connect the cable (26) to the second plug-in unit (30).

29. Circuit for an intelligent data line for identifying and managing cable or network-related characteristic data, the circuit (10) comprising a read / write memory (2), and a switching device (1), the switching device controlling the data flow between the data line (4) and the read / write memory (2) controls.

0. Circuit according to claim 29, characterized by the features according to one of claims 1 to 1 5.